FreeCalypso > hg > fc-tourmaline
view src/cs/drivers/drv_app/r2d/r2d_i.c @ 275:79cfefc1e2b4
audio mode load: gracefully handle mode files of wrong AEC version
Unfortunately our change of enabling L1_NEW_AEC (which is necessary
in order to bring our Calypso ARM fw into match with the underlying
DSP reality) brings along a change in the audio mode file binary
format and file size - all those new tunable AEC parameters do need
to be stored somewhere, after all. But we already have existing
mode files in the old format, and setting AEC config to garbage when
loading old audio modes (which is what would happen without the
present change) is not an appealing proposition.
The solution implemented in the present change is as follows: the
audio mode loading code checks the file size, and if it differs
from the active version of T_AUDIO_MODE, the T_AUDIO_AEC_CFG structure
is cleared - set to the default (disabled AEC) for the compiled type
of AEC. We got lucky in that this varying T_AUDIO_AEC_CFG structure
sits at the end of T_AUDIO_MODE!
| author | Mychaela Falconia <falcon@freecalypso.org> |
|---|---|
| date | Fri, 30 Jul 2021 02:55:48 +0000 |
| parents | 4e78acac3d88 |
| children |
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/** @file: r2d_i.c @author Christophe Favergeon @version 0.5 Purpose: Low level utilities functions for R2D */ /* Date Modification ------------------------------------ 06/02/2001 Create 10/18/2001 Version 0.5 for first integration with Riviera database (C) Copyright 2001 by Texas Instruments Incorporated, All Rights Reserved */ #include "rv/general.h" #include "rvf/rvf_api.h" #include "r2d/r2d_config.h" #include "r2d/r2d.h" #include "r2d/r2d_i.h" #include "r2d/r2d_independance_layer.h" #if (R2D_DEBUG == R2D_ON) #include <stdio.h> #endif #if (R2D_EMBEDDED_LCD == R2D_PC_COLOR_LCD) #include "Windows.h" #endif //////////////////////////////////////// // // GLOBALS // UINT32 *r2d_g_dithering_matrix; #if (R2D_ASM == R2D_ON) T_RVF_MUTEX * r2d_g_blit_mutex; T_R2D_DRAWING_MODE r2d_g_old_mode; R2D_BOOLEAN r2d_g_old_use_foreground; INT32 r2d_g_old_srcdst; UINT32 r2d_g_old_foreground_pixelvalue; UINT32 r2d_g_old_background_pixelvalue; #endif T_RVF_MUTEX * r2d_g_global_mutex; //////////////////////////////////////// // // Class definitions // const T_R2D_CLASS_SHAPE r2d_class_rectangle= { NULL, r2d_release_rectangle, r2d_draw_rectangle_shape, r2d_fill_rectangle_shape, r2d_clone_rectangle_shape, r2d_translate_rectangle_shape, r2d_point_in_rectangle_shape }; const T_R2D_CLASS_SHAPE r2d_class_circle= { NULL, r2d_release_circle, r2d_draw_circle_shape, r2d_fill_circle_shape, r2d_clone_circle_shape, r2d_translate_point_shape, r2d_point_in_circle_shape }; const T_R2D_CLASS_SHAPE r2d_class_ellipse= { NULL, r2d_release_ellipse, r2d_draw_ellipse_shape, r2d_fill_ellipse_shape, r2d_clone_rectangle_shape, r2d_translate_rectangle_shape, r2d_point_in_ellipse_shape }; const T_R2D_CLASS_SHAPE r2d_class_round_rectangle= { NULL, r2d_release_round_rectangle, r2d_draw_round_rectangle_shape, r2d_fill_round_rectangle_shape, r2d_clone_round_rectangle_shape, r2d_translate_rectangle_shape, r2d_point_in_round_rectangle_shape }; const T_R2D_CLASS_SHAPE r2d_class_arc= { NULL, r2d_release_arc, r2d_draw_arc_shape, r2d_fill_arc_shape, r2d_clone_arc_shape, r2d_translate_rectangle_shape, r2d_point_in_not_supported_shape }; const T_R2D_CLASS_SHAPE r2d_class_text= { NULL, r2d_release_text, r2d_draw_text_shape, r2d_fill_text_shape, r2d_clone_text_shape, r2d_translate_point_shape, r2d_point_in_not_supported_shape }; ////////////////////////////////// // // All globals must be protected // with semaphores T_R2D_FRAMEBUFFER* r2d_g_framebuffer; // Pointer for default initializations of graphical context T_R2D_FRAMEBUFFER *r2d_g_default_font_framebuffer; INT32 *r2d_g_default_font_metrics; INT32 *r2d_g_default_font_table; BOOLEAN r2d_g_event_was_sent; INT16 r2d_g_refresh_disabled; T_R2D_FONT_DESCRIPTION *r2d_g_font_configuration; ////////////////////////////////// // // Common C code // T_R2D_DRAWING_OP r2d_get_drawing_op(T_R2D_GC *gc,T_R2D_DRAWING_MODE mode) { if (((T_R2D_FRAMEBUFFER*)(gc->p_frame_buffer))->kind!=R2D_FULL_KIND) { return(r2d_g_lcd_operators[mode]); } else return(r2d_g_color_operators[mode]); } #if (R2D_ASM == R2D_ON) UINT32 * r2d_get_asm_drawing_op(T_R2D_GC *gc,T_R2D_DRAWING_MODE mode) { if (((T_R2D_FRAMEBUFFER*)(gc->p_frame_buffer))->kind!=R2D_FULL_KIND) { return(r2d_g_asm_lcd_operators[mode]); } else return(r2d_g_asm_color_operators[mode]); } #endif // Get max component UINT16 r2d_max_color(UINT16 red,UINT16 green, UINT16 blue) { UINT16 result=red; if (green > result) result=green; if (blue > result) result=blue; return(result); } // Get min component UINT16 r2d_min_color(UINT16 red,UINT16 green, UINT16 blue) { UINT16 result=red; if (green < result) result=green; if (blue < result) result=blue; return(result); } #if (R2D_DITHERING == R2D_ON) // Set element (x,y) of dithering or dithered matrix void r2d_set_dithering_matrix_entry(UINT32 *matrix,UINT32 elem,INT16 x,INT16 y) { UINT32 *p=matrix; p+=(x&1)+(y&1)*2; *p=elem; } #else #define r2d_set_dithering_matrix_entry(matrix,elem,x,y) #endif static UINT32 r2d_color_copy_operator(UINT32 old,UINT32 value) { return(value); } static UINT32 r2d_color_or_operator(UINT32 old,UINT32 value) { if ((value&0x00FFFFFF)==0) return(value); else return(old); } static UINT32 r2d_color_and_operator(UINT32 old,UINT32 value) { return(old & value); } static UINT32 r2d_color_xor_operator(UINT32 old,UINT32 value) { return(old ^ value) ; } static UINT32 r2d_color_not_copy_operator(UINT32 old,UINT32 value) { return(~value); } static UINT32 r2d_color_not_or_operator(UINT32 old,UINT32 value) { return(~(old | value)); } static UINT32 r2d_color_not_and_operator(UINT32 old,UINT32 value) { return(~(old & value)); } static UINT32 r2d_color_not_xor_operator(UINT32 old,UINT32 value) { return(~(old ^ value)) ; } static UINT32 r2d_color_erase_operator(UINT32 old,UINT32 value) { if ((value & 0xFFFFFF)==0xFFFFFF) return(0); else return(old); } UINT32 r2d_color_alpha_operator(UINT32 old,UINT32 value) { INT16 a,rs,gs,bs,rd,gd,bd; a=(value >> 24) & 0x0FF; value=~value; old=~old; bs=(value & 0xFF); value=value>>8; gs=(value & 0xFF); value=value>>8; rs=(value & 0xFF); value=value>>8; bd=(old & 0xFF); old=old>>8; gd=(old & 0xFF); old=old>>8; rd=(old & 0xFF); // Pixel value has been complemented before being // saved so that the white correspond to 0 and be // compatible with formulas for other modes. // But alpha value is not complemented // So a=0xFF correspond tranparency bd=((a)*bd+(0x100 - a)*bs) >> 8; gd=((a)*gd+(0x100 - a)*gs) >> 8; rd=((a)*rd+(0x100 - a)*rs) >> 8; old=0; old=old|(rd&0xFF); old=old<<8; old=old|(gd&0xFF); old=old<<8; old=old|(bd&0xFF); old=(~old) & 0x00FFFFFF; return(old); } const T_R2D_DRAWING_OPERATORS r2d_g_color_operators= { &r2d_color_copy_operator, &r2d_color_or_operator, &r2d_color_and_operator, &r2d_color_xor_operator, &r2d_color_not_copy_operator, &r2d_color_not_or_operator, &r2d_color_not_and_operator, &r2d_color_not_xor_operator, &r2d_color_alpha_operator, &r2d_color_erase_operator }; void r2d_convert_foreground_color_color(T_R2D_GC *gc,UINT32 color) { UINT32 lcolor; gc->foreground_pixel_value=r2d_alpha(color); gc->foreground_pixel_value<<=24; lcolor=0; lcolor|=r2d_red(color); lcolor=lcolor<<8; lcolor|=r2d_green(color); lcolor=lcolor<<8; lcolor|=r2d_blue(color); gc->foreground_pixel_value|=(~lcolor) & 0x00FFFFFF; } // Return the pixel value to write on the LCD or the offscreen // pixmap // LCD DEPENDENT void r2d_convert_background_color_color(T_R2D_GC *gc,UINT32 color) { UINT32 lcolor; gc->background_pixel_value=r2d_alpha(color); gc->background_pixel_value<<=24; lcolor=0; lcolor|=r2d_red(color); lcolor=lcolor<<8; lcolor|=r2d_green(color); lcolor=lcolor<<8; lcolor|=r2d_blue(color); gc->background_pixel_value|=(~color) & 0x00FFFFFF; } // Select pixel of a color framebuffer as being // a foreground or background one BOOLEAN r2d_color_framebuffer_foreground_pixel(UINT32 lcd_value,T_R2D_GC_PTR src_gc) { if ((lcd_value & 0x00FFFFFF)) return(TRUE); else return(FALSE); } INT32 r2d_ptree_find(INT32 *tree,INT32 unicode) { INT32 state=0; INT32 current_block; current_block=unicode>>R2D_PTREE_SHIFT; while (tree[state+R2D_PTREE_TYPE]!=R2D_PTREE_T_LEAF) { if (current_block & tree[state+R2D_PTREE_PREFIX]) state=tree[state+R2D_PTREE_RIGHT]; else state=tree[state+R2D_PTREE_LEFT]; } if (tree[state+R2D_PTREE_UNICODE_BLOCK]==current_block) { return(unicode + (tree[state+R2D_PTREE_CONVERSION])); } else return(0); } INT32 r2d_get_point_side(INT16 x,INT16 y,INT32 sa,INT32 sb) { INT32 ret; ret=((sb>>1)*x+((-sa)>>1)*y); return(ret); } BOOLEAN r2d_check_is_in_arc_region(INT16 x,INT16 y,T_R2D_ARC_REGION *rgn) { INT32 a,b; a=r2d_get_point_side(x,y,rgn->sa,rgn->sb); b=r2d_get_point_side(x,y,rgn->ea,rgn->eb); /*if (a&&b) r2d_set_foreground_color_with_argb(r2d_g_lcd_gc,0,255,0,0); else if (!a && !b) r2d_set_foreground_color_with_argb(r2d_g_lcd_gc,0,0,255,0); else if (!a && b) r2d_set_foreground_color_with_argb(r2d_g_lcd_gc,0,0,0,255); else if (a && !b) r2d_set_foreground_color_with_argb(r2d_g_lcd_gc,0,255,255,0);*/ if (rgn->one_sector==0) return(((a>=0) && (b>=0))); else return(!(!(a>=0) && !(b>=0))); } void r2d_arc_region_y_reflect(T_R2D_ARC_REGION *rgn) { rgn->sa=-rgn->sa; rgn->ea=-rgn->ea; } void r2d_arc_region_x_reflect(T_R2D_ARC_REGION *rgn) { rgn->sb=-rgn->sb; rgn->eb=-rgn->eb; } void r2d_arc_region_diagonal_reflect(T_R2D_ARC_REGION *rgn) { INT32 tmp; tmp=rgn->sa; rgn->sa=rgn->sb; rgn->sb=tmp; tmp=rgn->ea; rgn->ea=rgn->eb; rgn->eb=tmp; }